Methods and apparatus to deliver therapeutic, non-ultraviolet electromagnetic radiation to inactivate infectious agents and/or to enhance healthy cell growth via a catheter residing in a body cavity

ABSTRACT

Methods and apparatus provide therapeutic electromagnetic radiation (EMR) for inactivating infectious agents in, on or around a catheter residing in a patient&#39;s body cavity and/or for enhancing healthy cell growth. The method comprises transmitting non-ultraviolet therapeutic EMR substantially axially along an optical element in a lumen of the catheter body and/or the catheter body. Through delivery of the therapeutic EMR to particular infected areas and/or areas requiring tissue healing. The methods and apparatus of the present disclosure inactivate the major sources of infection in, on, and around catheters and/or enhance healthy cell growth around catheters.

RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 13/801,750, filed on Mar. 13, 2013 and entitled METHODS AND APPARATUS TO INACTIVATE INFECTIOUS AGENTS ON A CATHETER RESIDING IN A BODY CAVITY and is also a continuation-in-part of U.S. application Ser. No. 15/424,732, filed Feb. 3, 2017 and entitled METHOD AND APPARATUS FOR REMOVABLE CATHETER VISUAL LIGHT THERAPEUTIC SYSTEM. This application also claims the benefit of U.S. Provisional Application No. 61/686,432 that was filed Apr. 5, 2012, for an invention titled HINS LASER LIGHT CATHETER, which is hereby incorporated by this reference as if fully set forth herein.

TECHNICAL FIELD

The present invention is a method and apparatus to provide therapeutic doses of non-ultraviolet light to inactivate infectious agents residing on, within, or generally around a catheter while the catheter is residing within a body cavity and/or to stimulate healthy cell growth causing a healing effect. In particular, the disclosure is a medical device assembly that utilizes non-ultraviolet visual therapeutic electromagnetic radiation (EMR) at a high enough intensity to stimulate healthy cell growth causing a healing effect and/or to reduce or eliminate infectious agents in, on, and around a catheter while it resides inside a body cavity.

Various exemplary embodiments of the present invention are described below. Use of the term “exemplary” means illustrative or by way of example only, and any reference herein to “the invention” is not intended to restrict or limit the invention to exact features or steps of any one or more of the exemplary embodiments disclosed in the present specification. References to “exemplary embodiment,” “one embodiment,” “an embodiment,” “some embodiments,” “various embodiments,” and the like, may indicate that the embodiment(s) of the invention so described may include a particular feature, structure, or characteristic, but not every embodiment necessarily includes the particular feature, structure, or characteristic. Further, repeated use of the phrase “in one embodiment,” or “in an exemplary embodiment,” do not necessarily refer to the same embodiment, although they may.

BACKGROUND

Catheters are commonly used as channels to inject medications or retrieve fluid samples in a patient. Each catheter comprises a tube, usually derived from plastic or other polymers, such as silicone, polyurethane, and the like, that is inserted into an area of the body and may contain one or more separate lines in which these fluids may be delivered or retrieved. A “lumen” designates a pathway in the catheter that goes from outside the body to inside the body. Catheters are used in various applications, including intravascularly, abdominally, urologically, gastrointestinally, ophthalmically, within the respiratory tract, within cranial space, within the spinal column, and the like. In all cases, the catheter is placed inside of a space in the body where the catheter resides, herein referred to as a “body cavity”. These devices frequently give rise to infections caused by growth of infectious agents in, on, and around the catheter. Infectious agents can include bacteria, fungi, viruses, or the like that enter the body and lead to illness of a patient. Depending on the location of the catheter placement, these infections can arise in the form of urinary tract infections, blood stream infections, soft tissue infection, and the like.

Catheter related infections (CRIs) are a large problem in medicine, leading to high morbidity and mortality rates. Current methods of reducing or eliminating the number of infectious agents in and on a catheter are of low efficacy. Typically, catheters will be removed if they are suspected to be harboring infectious agents, increasing both the cost associated with treatment and patient discomfort. Various methods to deter or eliminate growth of infectious agents in catheters have been attempted, such as using sterile handling techniques, antibiotics, and replacing the catheter when an infection is suspected. Despite these techniques, infections resulting from catheters remain a major problem. According to the Centers for Disease Control and Prevention, over 31,000 people died specifically from catheter-related bloodstream infections in 2010. These infections, along with urinary tract infections, gastrointestinal infections, and other infections from catheters, increase both medical costs and patient discomfort.

Catheters come in various sizes. Those that are smaller in diameter, such as many PICC lines (peripherally inserted central catheters), have small diameter lumens. Such smaller diameter catheters may be suitable for prolonged insertion. Consequently, with smaller diameter catheters, there may be inadequate thickness to the catheter wall to carry a sterilization and/or healthy growth enhancing delivery system.

The use of ultraviolet (UV) light, disinfecting chemicals, catheters impregnated with drugs, to name a few, have been attempted to reduce the prevalence of infection. Many patents have attempted to utilize UV light to disinfect catheters. Unfortunately, UV light is well known to cause damage to living cells. Methods to disinfect connectors, stopcocks, and valves using sterilizing electromagnetic radiation (EMR) have also been attempted using 405 nm light to sterilize these points, but these methods neglect disinfection of the catheter body as well as the tip of the catheter.

The emergence of infectious agents that are resistant to current treatments, such as methicillin-resistance staphylococcus aureus (MRSA), further substantiate the need for another treatment of CRIs. To reduce the costs associated with having to remove and replace the catheters from the patient, there is a need for a catheter that can be sterilized while residing in the patient. Additionally, it would be advantageous to be able to stimulate healthy cell growth by providing therapeutic EMR via the indwelling catheter.

Immediate disinfection after placement could help prevent the growth of biofilm on the catheter. Biofilm consists of extracellular polymeric material created by microorganisms after they adhere to a surface. This biofilm facilitates the growth of infectious agents and is very difficult to break down once it has begun to grow.

The growth of infectious agents can result from agents outside the patient (at the point of access as the catheter crosses the skin or from the catheter hub) or from inside the patient, wherein infectious agents already in the body attach to the surface of the catheter and proliferate. Scientific literature suggests that approximately 65% of CRI's come from infectious agents residing on the skin of the patient (S. Öncü, Central Venous Catheter—Related Infections: An Overview with Special Emphasis on Diagnosis, Prevention and Management. The Internet Journal of Anesthesiology. 2003 Volume 7 Number 1). These agents travel down the outside of the catheter and colonize the catheter tip. For short term catheterization, this is believed to be the most likely mechanism of infection (Crump. Intravascular Catheter-Associated Infections. Eur J Clin Microbiol Dis (2000) 19:1-8). Thirty percent (30%) of CRIs are believed to come from a contaminated hub, in which infectious agents travel down the interior of the catheter (Öncü). This is believed to be the most likely mechanism of infection for long-term catheterization (Crump).

EMR in the range of 380-900 nm has been shown to be effective in killing infectious agents. Research done by a group at the University of Strathclyde shows that light in this range is effective in killing surface bacteria in burn wards without harming the patients (Environmental decontamination of a hospital isolation room using high-intensity light. J Hosp Infect. 2010 November; 76(3):247-51). Published patent application 2010/0246169, written by the members who conducted the study, utilizes ambient lighting to disinfect a large surrounding area. The mechanism proposed by the team suggests that light in this range leads to photosensitization of endogenous porphyrins within the bacteria, which causes the creation of singlet oxygen, leading to the death of the bacteria. (Inactivation of Bacterial Pathogens following Exposure to Light from a 405-Nanometer Light-Emitting Diode Array. Appl Environ Microbiol. 2009 April; 75(7): 1932-7).

Heretofore, however, there has never been apparatus or methods for making or using such apparatus to safely and effectively disinfect a catheter while it is still implanted in a patient. Accordingly, there exists a need for a methods and apparatus designed to deliver non-antibiotic, bactericidal therapeutics in-vivo. Such a methods and apparatus, using novel technology, may provide removable delivery of safe, effective, and reproducible disinfection and/or enhance healthy cell growth.

SUMMARY OF THE INVENTION

The exemplary embodiments of this disclosure relate to a medical device assembly for insertion into a cavity of a patient's body and for delivery and retrieval of fluids. The assembly comprises an electromagnetic radiation (EMR) source for providing non-ultraviolet, therapeutic EMR having intensity sufficient to inactivate one or more infectious agents and/or to enhance healthy cell growth. This catheter has an elongate catheter body with at least one internal lumen, a coupling end, and a distal end. This distal end is insertable into the cavity of the patient's body whether the cavity is venous, arterial, gastrointestinal, abdominal, urological, respiratory, cranial, spinal, or the like, wherein the indwelling catheter body directs both the fluid and the propagation of the therapeutic EMR axially relative to the catheter body for radial delivery into the patient's body and/or at the distal end. An optical element disposed within a lumen of the catheter body and/or within the catheter body acts conducive to the axial propagation of the therapeutic EMR relative to the catheter body. The optical element or another optical element also may be disposed to act conducive to propagation of therapeutic EMR through at least one coupling element to connect the EMR component to the insertable catheter component.

For the purposes of this disclosure the use of the term “therapeutic” should be understood to mean of or relating to the treatment of disease, including reducing or eliminating infectious agents, as well as serving or performed to maintain health, including enhancing healthy cell growth.

The exemplary medical device assembly comprises an EMR source, an EMR conduction system, and at least one coupling to connect the EMR source to the EMR conduction system. The EMR source provides non-ultraviolet, therapeutic EMR having intensity sufficient to inactivate one or more infectious agents and/or to stimulate healthy cell growth causing a healing effect. In at least one exemplary embodiment, the EMR conduction system may be at least partially insertable into and removable from the lumen of an indwelling catheter.

In some exemplary embodiments, methods and apparatuses are provided for effectively sterilizing a catheter and the surrounding area while in a body cavity. Such medical device assemblies use sterilizing EMR to reduce or eliminate the count of infectious agents in, on, or around the catheter while in a body cavity.

The EMR source can be from a single or group of EMR sources including, but not limited to, a light emitting diode, a semiconductor laser, a diode laser, an incandescent (filtered or unfiltered) and a fluorescent (filtered or unfiltered) light source. This EMR source provides non-ultraviolet, therapeutic EMR providing one or more wavelengths in the range of above 380 nm to about 904 nm. In order to provide sufficient inactivation of infectious species and/or stimulation of healthy cell growth, each EMR wavelength should be of a narrow spectrum and centered around one wavelength from the group. The intensity should be sufficient to inactivate one or more infectious agents and/or to stimulate healthy cell growth causing a healing effect. This group includes several wavelengths centered about: 400 nm, 405 nm, 415 nm, 430 nm, 440 nm, 445 nm, 455 nm, 470 nm, 475 nm, 632 nm, 632.8 nm, 640 nm, 650 nm, 660 nm, 670 nm, 680 nm, 780 nm, 808 nm, 830 nm, and 904 nm.

The EMR source may require drivers and electronic support for full functionality. Consideration should be given to accommodating the support hardware and/or software, which may encompass a significant portion of the EMR source's functionality and efficacy. It is possible that the EMR source may generate heat, which could be detrimental to the EMR source and may need to be limited.

This disclosure describes a catheter having an elongate catheter body with at least one internal lumen, a coupling end and a distal end, the distal end being insertable into the cavity of the patient's body. The catheter body is meant to direct both the fluid and the therapeutic EMR axially relative to the catheter body for delivery into the patient's body at the distal end. This disclosure includes an optical element disposed within the catheter body and conducive to the axial propagation of the therapeutic EMR through the catheter body. Finally, this disclosure describes at least one coupling element to connect the radiation source to the catheter body.

The sterilizing EMR is transmitted down a specialized path within the catheter via an optical element conducive to the axial propagation of the light. Various methods could be used to facilitate axial propagation of the light relative to the catheter, including a reflective coating within a line of the catheter, a fiber optic cable, a lens, a waveguide, or the like. The light source can be a light-emitting diode (LED), laser, fiber optic filament, or the like.

One exemplary embodiment of the EMR source and support components is simplified to contain only the EMR source and necessary components. In another exemplary embodiment of the EMR conduction system, a passive heat sink is required to diffuse the heat generated into the surrounding environment. In yet another exemplary embodiment of the EMR source, a heat sink may be couple to at least one fan to actively dissipate heat generated by the EMR source.

Of particular interest to this disclosure is the use of light between 380 nm and about 900 nm wavelengths. Additionally, the intensity and power of the light emitted bear significantly on the inactivation of infectious agents, thus a range of radiant exposures covering 0.1 J/cm² to 1 kJ/cm² and a range of powers from 0.005 mW to 1 W, and power density range covering 1 mW/cm² and 1 W/cm² are of interest for these exemplary device assemblies and methods. These ranges of wavelengths, power densities, and radiant exposures have been shown to have either antimicrobial effects or positive biological effects on healing tissue. These positive biological effects include reduction of inflammatory cells, increased proliferation of fibroblasts, stimulation of collagen synthesis, angiogenesis inducement and granulation tissue formation.

For each exemplary embodiment described herein, the EMR conduction system and method for disinfection/healing could be utilized in an adjustable or predetermined duty cycle. If treatments begin immediately after sterile procedure was initiated, device related infections may be inhibited. This includes device related biofilm growth.

A treatment may include at least one wavelength of therapeutic EMR that acts as a predominant wavelength selected to sterilize one or more target organisms and selected from the group of wavelengths centered about 400 nm, 405 nm, 415 nm, 430 nm, 440 nm, 445 nm, 455 nm, 470 nm, 475 nm, 660 nm, and 808 nm. Or, a predominant wavelength selected to promote healing and healthy cell growth may be selected from the group of wavelengths centered about 632 nm, 632.8 nm, 640 nm, 650 nm, 660 nm, 670 nm, 680 nm, 780 nm, 808 nm, 830 nm, and 904 nm. Another treatment may include alternating the predominant wavelength between a first predominant wavelength and a second predominant wavelength (differing from the first predominant wavelength) in a selected treatment pattern. Further, sterilizing EMR and EMR that stimulates healthy cell growth may be transmitted simultaneously in tandem or alternatively.

A method for constructing an exemplary medical device assembly for insertion into a cavity of a patient's body and for delivery of a fluid to or retrieval from the patient's body may comprise the steps of: providing a catheter having an elongate catheter body with at least one internal lumen, a coupling end and an distal end, the distal end being insertable into the cavity of the patient's body; applying an optical element within the at least one lumen of the catheter body and/or within a wall of the catheter body, the optical element being conducive to the axial propagation of therapeutic EMR relative to the catheter body; and coupling an EMR source to the catheter body, the EMR source for providing non-ultraviolet, therapeutic EMR having an intensity sufficient to inactivate one or more infectious agent and/or to enhance healthy cell growth.

In one exemplary embodiment, the device uses a catheter that is inserted into a cavity of a patient's body, wherein said catheter allows both fluid and therapeutic EMR to travel axially relative to the catheter body. The catheter also contains at least one coupling lumen to connect an EMR source that will transmit the therapeutic EMR through the coupling lumen and axially relative to the catheter line. A coupling element in this context will usually refer to a typical hub on the therapeutic EMR source.

In at least one exemplary embodiment, a removably insertable EMR conduction system may comprise at least one optical element having an elongate body conducive to the axial propagation of the therapeutic EMR through the elongate body. This elongate body may have an exterior surface between a coupling end and a distal end. The exterior surface may have at least one radial emission portion wherein the radial emission facilitates the radial emission of therapeutic EMR from the elongate body proximate each radial emission portion.

At least one coupling connects the radiation source to the EMR conduction system and, in some exemplary embodiments, may comprise at least one feature that allows for the coupling to be readily removable from the EMR conduction system. The exemplary coupling may be achieved by utilizing a uniquely designed connection, a pre-manufactured coupling system, or any combination thereof that optimizes the coupling efficiency and utility. Further, such couplings couple the removably insertable EMR conduction system to the EMR source and may comprise more than one coupling with an intermediate section optimized to further the propagation of the EMR. In one exemplary embodiment, the EMR source may be coupled to a patch cable or EMR conduction extending segment, which is then coupled to the formal removably insertable EMR conduction system.

The optical element further may comprise at least one optical feature selected from a group of optical features such as a reflective surface, an optically transmissible material, a lens, a fiber optic filament, and any combination thereof. The optical element also may be capable of transmitting more than one wavelength or intensity EMR. Multiple wavelengths may be transmitted simultaneously, one after another or in tandem, or a combination thereof (for example, one constantly on and the other wavelength pulsed). Multiple intensities may be transmitted through the same element simultaneously. Alternating patterns of light treatments may also be transmitted.

The EMR conduction system may be configured to insert, at least partially, into one of any number of catheters, such as by way of example only and not to be limiting: a central venous catheter, a peripheral insertion catheter, a peripheral insertion central catheter, a midline catheter, a jugular catheter, a subclavian catheter, a femoral catheter, a cardiac catheter, a cardiovascular catheter, a urinary Foley catheter (see FIGS. 13 and 14), an intermittent urinary catheter, an endotracheal tube, a dialysis catheter (whether hemodialysis or peritoneal dialysis), a gastrointestinal catheter, a nasogastric tube, a wound drainage catheter, or any similar accessing medical catheter or tube that has been inserted into a patient for the purpose of delivering or retrieving fluids or samples.

One exemplary embodiment of the EMR conduction system has an optical element comprising a single, insertable optical fiber. With a single optical fiber, the single fiber may allow light to transmit radially or axially at various sections along its length. For sections where light will transmit radially, the exterior surface of the optical element may be altered to facilitate the radial emission of the EMR. The alteration of the exterior surface may be achieved by chemical etching, physical etching, or electromagnetic ablation through plasma or lasers to create various radial emission portions along the length of the optical fiber. The radial emission portions permit light to emit radially from the optical fiber.

For purposes of this disclosure, light emitted radially means that the light has a radial component. Hence, the light emitted radially may emit perpendicularly and/or obliquely to the central axis of the optical fiber at the axial point of emission.

For embodiments having radial emission sections, the material comprising the optical fiber may be selected from a group of materials comprising optical fibers including plastic, silica, fluoride glass, phosphate glass, chalcogenide glass, and any other suitable material that is capable of axial light propagation and surface alteration to achieve radial emission. In addition, the optical fibers may be single mode, multi-mode, or plastic optical fibers that may have been optimized for alteration using a chemical, physical, or electromagnetic manufacturing alteration process. The optical fibers may also be optimized for alteration post-production.

Yet another exemplary embodiment employs a physical abrasion method of alteration to modify the EMR conduction system comprised of at least one optical fiber. This fiber would be utilized based on its optimal optical response to the physical abrasion process. This process may include, but is not limited to, sanding, media blasting, grinding, buffing, or media blasting at least one section of the optical fiber. The physical abrasion process would also necessarily be optimized in terms of the extent of physical abrasion to optimize the appropriate radial EMR emission or lack thereof. This may be accomplished by adjusting at least one of the velocity, acceleration, pressure, modification time, or abrasion material utilized in modifying the optical fiber.

Yet another exemplary embodiment employs microscopic porous structures suspended within the optical fiber to achieve radial transmission of light. These microscopic structures may be positioned within the core and/or core-cladding boundary of the optical fiber. The microscopic structures having a refractive index lower than the region free of microscopic structures. The microscopic structures may be a material added to the optical fiber core or the core-cladding boundary, such as a metal, rubber, glass, or plastic. The microscopic structures may also be the lack of material creating an aberration within the optical fiber core or the core-cladding boundary. For example, the presence of microscopic bubbles in the optical fiber core would create an aberration or imperfection that would alter the materials refractive index, resulting in EMR being emitted radially from the optical fiber.

Another exemplary embodiment may comprise at least one optical fiber with cladding altered to optimize the radial or axial propagation of EMR. For example, the cladding may be altered to at least partially remove or thin the cladding in order to achieve partial radial transmission of EMR. Another example could include an optical fiber with only certain portions containing cladding, the EMR transmitting axially in the clad portions and at least partially axially and radially in the non-clad portions.

Yet another exemplary embodiment achieves uniform radial transmission wherein the radial emission portion of the optical fiber has substantially equivalent intensity over the length of the radial emission portion along the optical fiber. This may be done through chemical etching, physical etching, plasma ablation, or laser ablation in a gradient pattern. By altering at least one of the velocity, acceleration, pressure gradients, flow, modification time, or modification material or process, it is possible to achieve radial transmission equivalency throughout each portion or the entire length of the modified optical fiber. During manufacturing, a gradient-provided uniformity also may be achieved through addition of microscopic structures positioned within the core and/or core-cladding boundary in a gradient pattern. Also, radial transmission uniformity achieved through gradient cladding or core features are contemplated for achieving desired radial emission, whether substantially uniform over a portion length or varying as desired.

Still another exemplary embodiment achieves a gradient radial transmission wherein at least one portion of the optical fiber emits EMR radially in a gradient distribution. The gradient distribution may also be accomplished through chemical etching, physical etching, plasma or laser ablation in a uniform or gradient pattern. By altering at least one of the velocity, acceleration, pressure gradients, flow, modification time, or modification material or process, it is possible to achieve a gradient radial transmission throughout a portion of the optical fiber. This may also be achieved through addition of microscopic structures positioned within the core and/or core-cladding boundary.

A further exemplary embodiment of a removably insertable EMR conduction system comprises an optical element such as at least one LED, its associated wiring components, and a scaffold. The LED(s) may emit EMR based on the LED's inherent distribution, or may utilize another optical element, such as a lens or mirror, to focus or diffuse the EMR in the direction of interest. In addition, more than one LED could be arranged in an array to appropriately emit EMR for maximal therapeutic benefit. The LED(s), together with associated wiring components may be permanently or removably attached to the scaffold, which allows for removable insertion of the EMR conduction system into a catheter. The scaffold may be rigid, semi-rigid, malleable, elastic, or flexible, or any combination thereof.

In another exemplary embodiment, a catheter with multiple lumens for fluid injection or retrieval contains a separate lumen for transmission of the therapeutic EMR. Each lumen may have a separate proximal catheter hub assembly. These internal lumens converge at a convergence chamber, where individual internal lumens consolidate into a single elongated catheter body while retaining their individual internal paths. Such exemplary device may include use of an optical method for diverting the radiation between the convergence chamber and axially through the designated catheter internal lumen.

Samples retrieved through the distal end are often used to characterize the type of infection. One exemplary embodiment of the disclosure focuses on maintaining axial propagation of the light relative to the catheter and delivering therapeutic light of sufficient intensity to the distal end of the catheter to reduce or eliminate the count of infectious agents residing thereon.

In yet another exemplary embodiment, the medical device assembly aforementioned would be used in a urological setting. The catheter (such as a Foley catheter) would be placed into the urethra and bladder of the urinary tract.

In yet another exemplary embodiment, the medical device assembly aforementioned would be used in a gastrointestinal setting.

In yet another exemplary embodiment, the medical device assembly aforementioned would be used in an intravascular setting.

In yet another exemplary embodiment, the medical device assembly aforementioned would be used within the cranial cavity of a patient.

In yet another exemplary embodiment, the medical device assembly aforementioned would be used within the spinal cavity of a patient.

In still another exemplary embodiment, the medical device assembly aforementioned would be used within an ophthalmic cavity of a patient.

In still another exemplary embodiment, the medical device assembly would be used within a dialysis catheter (whether hemodialysis or peritoneal dialysis).

BRIEF DESCRIPTION OF THE DRAWINGS

Exemplary embodiments of the invention will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. Understanding that these drawings depict only exemplary embodiments and are, therefore, not to be considered limiting of the invention's scope, the exemplary embodiments of the present disclosure will be described with additional specificity and detail through use of the accompanying drawings in which:

FIG. 1 is a perspective view of an exemplary embodiment of a double lumen catheter and an EMR component with the connection in an exploded view to illustrate the connection of the EMR source to the catheter;

FIG. 2 is a schematic view of another exemplary embodiment of a tunneled triple lumen catheter as inserted into a body cavity through an insert incision in the patient's chest;

FIG. 3 is a schematic view of yet another exemplary embodiment of a tunneled triple lumen catheter, an insertable optical element, and an EMR component, showing the triple lumen catheter as inserted into a body cavity through an insert incision in the patient's arm and the connection in an exploded view to illustrate the connection of the EMR source to the catheter and the insertion of the optical element partially inserted into the catheter;

FIG. 4 is a perspective, partially exploded view of still another exemplary embodiment of a dual lumen catheter with the insertable optical element disposed outside the catheter and showing an intermediate coupling;

FIG. 5 is a perspective view of the exemplary dual lumen catheter of FIG. 4 with the insertable component disposed partially inside the catheter;

FIG. 6A is a cross sectional view along line B-B of FIG. 5 showing an exemplary embodiment of a cladding-encased optical element as centered within a lumen of the catheter line tubing;

FIG. 6B is a cross sectional view along line B-B of FIG. 5 showing an exemplary embodiment of the cladding-encased optical element non-centered within a lumen of the catheter line tubing;

FIG. 6C is a cross sectional view along line B-B of FIG. 5 showing another exemplary embodiment of a bare fiber optical element as centered within a lumen of the catheter line tubing (FIGS. 6A-C are illustrative cross sectional views of alternative optical elements as disposed within a single-lumen catheter);

FIG. 7 is a perspective, partially exploded view of an exemplary dual lumen catheter with the insertable component disposed partially inside the catheter and showing an intermediate coupling;

FIGS. 8A-D is a series of elevation views of several exemplary embodiments of an insertable optical element with varying locations, lengths, and degrees of alteration, and with an optical element connector shown as transparent to better illustrate internal features that are shown in phantom lines; FIG. 8A is an elevation view of an exemplary embodiment of an optical element having no radial emission portion; FIG. 8B is an elevation view of another exemplary embodiment of an optical element having a single radial emission portion disposed over an intermediate segment between the coupling end and the distal end of the optical element; FIG. 8C is an elevation view of yet another exemplary embodiment of an optical element having a single radial emission portion disposed over substantially the entire distance between the coupling end and the distal end of the optical element; FIG. 8D is an elevation view of still another exemplary embodiment of an optical element having multiple radial emission portions, one disposed over an intermediate segment between the coupling end and the distal end of the optical element, and another proximate the distal end.

FIG. 9 shows cross-sectional views of multiple portions of an exemplary insertable optical element (similar to that shown in FIG. 8C) with various EMR radial, gradient emission levels;

FIG. 10 shows the cross-sectional views of various gradient emission levels of FIG. 9 showing the sections with EMR ray diagrams of internal reflection, and relative radial emission;

FIG. 11 shows cross-sectional views of various exemplary dispersals of microscopic structures (such as flecks or bubbles) within a fiber optic's core, cladding, and the core/cladding boundary;

FIG. 12 is a schematic view of a treatment being applied to the insertable optical elementdistal end;

FIG. 13 is a perspective, partially exploded view of an exemplary embodiment of a urinary catheter with the insertable optical element shown partially inserted into an input port and the ballon cuff inflated; and

FIG. 14 is a schematic view of another exemplary embodiment of a urinary catheter positioned to drain urine and to provide therapeutic EMR.

REFERENCE NUMERALS catheter 10 patient's body 12 optical element 14 line tubing 16 EMR conduction system 18 electromagnetic radiation component 20 insertable catheter component 22 elongate body 24 electromagnetic radiation power source 26 coupling element 28 internal lumen 30 proximal catheter hub assembly 32 distal end 34 aperture 35 elongate catheter body 36 balloon cuff 37 catheter of varying lengths 38 urethra 39 convergence chamber 40 bladder 41 termination of the optical element 42 input port 43 flexible protection tubing 44 output port 45 line clamp 46 transdermal area 48 optical assembly 50 intermediate coupling 52 patch cable 54 EMR conduction extending segment 56 forward connector 58 rearward connector 60 exterior surface 62 distal end 64 core 66 cladding 68 cladding-encased fiber optic 70 bare fiber optic 72 inner diameter 74 outer diameter 76 void 78 core-cladding boundary 80 cladding outer boundary 82 catheter wall 84 connecting element 88 EMR hub connector 90 collimating lens 92 optical element connector 94 alignment shaft 98 an aligning bore 99 non-modified optical span 100 segment-modified optical span 102 radial emission portion 103 fully-modified optical span 104 elongated radial emission portion 105 multi-modified optical span 106 modified tip portion 107 first section 108 microscopic structures free area 109 second section 110 minimal concentration 111 third section 112 moderate concentration 113 fourth section 114 maximal concentration 115 microscopic structures 117 first dispersal 121 control device 122 second dispersal 123 wand 124 third dispersal 125 acid spray 126 outer region 127 inner region 129 boundary region 131 adapter 150 securing sleeve 152 drain tube 154 operational control features 156 display 158 optical jack 160 fluid flow/EMR propagation 162 urine flow 164 insertion site A

DETAILED DESCRIPTION

Exemplary embodiments of the present disclosure will be best understood by reference to the drawings, wherein like parts are designated by like numerals throughout. It will be readily understood that the components of the exemplary embodiments, as generally described and illustrated in the Figures herein, could be arranged and designed in a wide variety of different configurations. Thus, the following more detailed description of the exemplary embodiments of the apparatus, system, and method of the present disclosure, as represented in FIGS. 1 through 11, is not intended to limit the scope of the invention, as claimed, but is merely representative of exemplary embodiments.

The phrases “attached to”, “secured to”, and “mounted to” refer to a form of mechanical coupling that restricts relative translation or rotation between the attached, secured, or mounted objects, respectively. The phrase “slidably attached to” refer to a form of mechanical coupling that permits relative translation, respectively, while restricting other relative motions. The phrase “attached directly to” refers to a form of securement in which the secured items are in direct contact and retained in that state of securement.

The term “abutting” refers to items that are in direct physical contact with each other, although the items may not be attached together. The term “grip” refers to items that are in direct physical contact with one of the items firmly holding the other. The term “integrally formed” refers to a body that is manufactured as a single piece, without requiring the assembly of constituent elements. Multiple elements may be formed integral with each other, when attached directly to each other to form a single work piece. Thus, elements that are “coupled to” each other may be formed together as a single piece.

The word “exemplary” is used herein to mean “serving as an example, instance, or illustration.” Any embodiment described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other embodiments. While the various aspects of the embodiments are presented in drawings, the drawings are not necessarily drawn to scale unless specifically indicated.

Referring now to FIG. 1, a catheter 10 is insertable into a patient's body 12. An assembly of the present disclosure comprises a non-ultraviolet, electromagnetic radiation (EMR) component 20, and an insertable catheter component 22. The non-ultraviolet, EMR component 20 broadly comprises an elongate body 24 used to enclose the EMR power source 26 and a coupling element 28 to couple the two components of the assembly. The EMR used manifests as visible light emitted in a range from 380 nm to 904 nm having a high intensity sufficient to create a therapeutic effect such as inactivating one or more infectious agents and/or enhancing healthy cell growth. In some embodiments, the EMR source 26 has an adjustable duty cycle length so that the EMR can be provided with appropriate desired intensity at the most effective times and for beneficial time periods.

The catheters 10 depicted in FIGS. 1-5 are exemplary multiple lumen catheters 10 each of which also comprises line tubing 16, one or more (in FIGS. 1, 4, and 5 two are shown, in FIGS. 2 and 3, three are shown) proximal catheter hub assemblies 32, an elongate catheter body 36, a distal end 34 with one or more apertures 35 that open into internal lumens 30, and a convergence chamber 40. Each internal lumen 30 has an inner diameter (i.e., an interior surface dimension, for example see outer diameter 76 of FIG. 6A) and runs the length of the catheter 10, from the proximal catheter hub assembly 32, through the line tubing 16, the convergence chamber 40, and the elongate catheter body 36, to the distal end 34. Fluids may be injected into the lumen 30 and exit through the aperture 35 into the patient's body 12, or fluids may be drawn from the patient's body 12 through the aperture 35 into the lumen 30. Additionally, some catheters 10 may have inflatable balloon cuffs 37 (see FIGS. 13 and 14) that may seal the catheter 10 against the wall of the patient's body 12 cavity into which the catheter 10 is inserted. The optical element 14 is elongate may be a reflective coating or it may be a fiber optic with an outer diameter (i.e., an exterior surface dimension, for example see outer diameter 76 of FIG. 6A) sufficiently small to be insertable within at least one of the internal lumens 30 and may extend at least as far into the catheter 10 as a termination of the optical element 42, although the insertion may be less than that length if desired.

Catheters 10 suitable for use with an insertable optical element 14 may be of several different makes, sizes, and functions. For example, a urinary catheter 10 (see FIGS. 13 and 14) inserted through a patient's urethra 39 into a patient's bladder 41 may have an input port 43, an output port 45, and an inflatable balloon cuff 37 to facilitate draining urine from the patient's bladder 41 while permitting fluids (or in the case of the present disclosure therapeutic EMR) to be injected into the patient's body 12. As another example, catheters 10 that are translucent may be particularly suited to permit the passage of radially emitted EMR through the catheter wall 84 (see an exemplary catheter wall 84 in FIGS. 6A-C) to the tissue surrounding the catheter 10. Catheters 10 that have an interior surface dimension (inside diameter 74) sufficiently larger than the exterior surface dimension (outer diameter 76) of the insertable optical element 14 create a void 78 or passageway (see FIGS. 6A-C) that may permit the injection or withdrawal of fluid (liquid or gas) simultaneously through the catheter 10 while that insertable optical element 14 resides within the catheter 10.

Also, some catheters 10 have radiopacifiers embedded within the walls of the catheter 10 so that an image of where the catheter 10 is located within the patient's body 12 may be determined. However, some catheters 10 have no such radiopacifiers. In either case, it is contemplated by this disclosure that radiopacifiers may be contained in or on the insertable optical element 14 to provide detection of the location of the catheter 10 within the patient's body 12 when the catheter 10 does not have radiopacifiers, and to provide detection of the location of the insertable optical element 14 disposed within the catheter 10 whether or not the catheter 10 has radiopacifiers (this may require differing radiopacifiers in some instances so that the catheter 10 and the insertable optical element 14 may be distinguished).

With some exemplary embodiments, at least one of the proximal catheter hub assemblies 32 may have an optical fiber element alignment shaft 98 that aligns an optical element connector 94 and the insertable optical element 14.

FIGS. 2 and 3 show the catheter 10, in a schematic view, inserted at an insertion site A in the chest of the patient's body 12 (FIG. 2) and in an arm of the patient's body 12 (FIG. 3), respectively. The depiction shows how non-ultraviolet, therapeutic EMR may be delivered at the insertion site A and to other sites within the patient's body 12. At the insertion site A, the therapeutic EMR may be delivered to a transdermal area 48 to inactivate infectious agents in that area and to enhance healing of the insert site A. Similarly, proximate the distal end 34, in this case within the vena cava, therapeutic EMR may be delivered to inactivate infectious agents and/or to enhance healing in that proximate vicinity.

Referring specifically to FIG. 2 of the present disclosure, a schematic view of another embodiment of the medical device assembly comprises a non-ultraviolet, EMR component 20, and an insertable catheter component 22. The embodiment shown is specifically a tunneled triple lumen central line variation of the disclosure; however it should be understood that the catheter may encompass any type of accessing catheter 10 (e.g., vascular, gastrointestinal, etc.) without departing from the scope and spirit of the invention. The non-ultraviolet EMR component 20 is coupled to the proximal catheter hub assembly 32 of the insertable catheter component 22. The other coupling hubs 32 are available for axial propagation of fluid (whether by injection or retrieval). Each designated internal lumen 30 propagates the EMR or fluid between its proximal catheter hub assembly 32 and distal end 34.

Although the triple lumen catheters 10 of FIGS. 2 and 3 depict specific uses of the triple lumen catheter 10, it should be understood that a triple lumen embodiment may be a desirable option in areas where multiple fluid delivery or extraction is necessary simultaneously. For example, in hemodialysis, venous and arterial blood is exchanged simultaneously. Similarly, in peritoneal dialysis, fluids and dissolved substances (electrolytes, urea, glucose, albumin, and other small molecules) are exchanged from the blood by catheter access through peritoneum in the abdomen of a patient. This exemplary triple lumen embodiment allows for the delivery of therapeutic EMR simultaneously with such dialysis function.

The incision site A and the proximate transcutaneous region of the insertable catheter body 36 is often a high source of infections. To reduce infections at this site and in this region, a dedicated area 48 is a region that facilitates radial emission of the therapeutic EMR from the optical element 14 within the elongate catheter body 36. This allows the sterilizing EMR to irradiate outward and inactivate the infectious agents at the insertion site A and transcutaneous in that region.

Proximate the distal end 34 of the elongate catheter body 36, the optical element 14 discontinues at termination point 42 so that the therapeutic EMR can irradiate throughout the distal end 34 of the catheter 10 and the surrounding cavity area.

The EMR component 20 comprises the EMR power source 26 (FIGS. 2-5), a light source (not shown, such as a laser or the like), electrical circuitry (not shown), and optics (not shown, but dependent upon the light source) all housed within an elongate body 24. A coupling element 28 connects the EMR component 20 to an optical assembly 50. The optical assembly 50 comprises the insertable optical element 14 and the optical element connector 94. The combination of the EMR component 20, the coupling element 28, and the optical assembly 50, comprising the insertable optical element connector 94 and the insertable optical element 14, will be referred to herein as an EMR conduction system 18. In some embodiments, the EMR conduction system 18 is removable from its inserted disposition within the catheter 10. When the EMR conduction system 18 is insertably removable, therapeutic EMR may be directed into an existing indwelling catheter 10 in a retrofit context.

Of particular interest to each of the embodiments is the use of light having wavelengths ranging from above 380 nm and about 904 nm. Additionally, the intensity and power of the light emitted server to inactivate of infectious agents and/or to promote healing. A range of radiant exposures covering 0.1 J/cm² to 1 kJ/cm² and a range of powers from 0.005 mW to 1 W, and power density range covering 1 mW/cm² and 1 W/cm² are of interest for these exemplary device assemblies and methods. These ranges of wavelengths, power densities, and radiant exposures have been shown to have either antimicrobial effects or positive biological effects on healing tissue. These positive biological effects include reduction of inflammatory cells, increased proliferation of fibroblasts, stimulation of collagen synthesis, angiogenesis inducement and granulation tissue formation.

For each exemplary embodiment described herein, the EMR conduction system 18 and method for disinfecting/healing could be utilized in an adjustable or predetermined duty cycle. If treatments began immediately after sterile procedure has been initiated, device-related infections may be inhibited. This includes device-related biofilm growth.

Additionally, although a wavelength in a range from 380 nm to 904 nm with a sufficient intensity will inactivate one or more infectious agents and/or enhance healthy cell growth, more precise wavelengths may have more particular efficacy against certain infectious agents or for a desired healing purpose. It has been determined that sterilizing EMR of wavelengths including wavelengths centered about 400 nm, 405 nm, 415 nm, 430 nm, 440 nm, 455 m, 470 nm, 475 nm, 660 nm, and 808 nm have particular efficacy. A wavelength selected to promote healing and healthy cell growth may be selected from the group of wavelengths centered about 632 nm, 632.8 nm, 640 nm, 650 nm, 660 nm, 670 nm, 680 nm, 780 nm, 808 nm, 830 nm, and 904 nm.

The insertable catheter component 22, being capable of at least partially being inserted into a cavity of the patient's body 12 to deliver the non-ultraviolet, therapeutic EMR, comprises of at least one internal lumen 30, a proximal catheter hub assembly 32, and a distal end 34. An internal lumen 30 being simply defined as the internal path by which fluid or EMR may travel. In cases of a single or multi-lumen catheter 10, similar features in the drawings will be labeled with the same number. It should be noted that examples of multi-lumen catheters are described and depicted in the parent application (U.S. application Ser. No. 13/801,750, filed on Mar. 13, 2013) which has been incorporated into this application by a specific reference above. In multi-lumen embodiments, a dedicated single lumen may also be designated for the axial propagation of EMR and each additional lumen dedicated for the injection or retrieval of fluid axially. In this way both fluid and EMR can be axially propagated simultaneously through their individual lines and the EMR-delivering optical element 14 and fluids need not occupy the same lumen.

The distal end 34 being insertable into the cavity of the patient's body 12 at a determined incision site A, enables the elongate catheter body 36 to direct the delivery and/or retrieval of fluid and the therapeutic EMR axially relative to the elongate catheter body 36 for delivery into the patient's body 12. The elongate catheter body 36 is described as being an elongated catheter 10 having at least one internal lumen 30. Another embodiment of the present disclosure is depicted in FIG. 4, showing a perspective view of a dual lumen catheter 10 with the removable EMR conduction system 18 outside the catheter 10. The catheter 10 portion of the depiction shows flexible protection tubing 44 that protects the coupling of the proximal catheter hub assembly 32 with the line tubing 16 and also protects line tubing 16 from wear imposed by line clamps 46.

Therapeutic EMR will travel axially relative to the catheter 10 which may be of varying lengths 38 depending on its specific need. The fluids passing through the internal lumen 30 may be injected and contain pharmacological compounds (e.g., a drug) or may be retrieved biological fluids (e.g., blood, urine, or cerebral spinal fluid).

This figure depicts a multi-lumen embodiment of the disclosure. Each multi-lumen embodiment may contain a convergence chamber 40, at the point where individual internal lumens 30 converge into a single elongated catheter body 36 while retaining their individual internal paths. At the distal end 34 of the elongate catheter body 36, the optical element 14 discontinues at the termination point 42 so that the therapeutic EMR can irradiate throughout the distal end 34 of the catheter 10 and surrounding cavity area.

This embodiment also is fitted with flexible protection tubing 44 to protect the lumen at the proximal catheter hub assembly 32 and between the proximal catheter hub assembly 32 and convergence chamber 40. If manual line occlusion is necessary it may be performed with the line clamp 46.

FIG. 5 shows the dual lumen catheter 10 of FIG. 4 with the removably insertable EMR conduction system 18 partially inserted into one of the lumens 30 of the catheter 10.

FIG. 7 shows an exploded perspective view of an exemplary EMR conduction system 18 as partially inserted into the proximal catheter hub assembly 32 and an internal lumen 30. With this exemplary embodiment, an intermediate coupling 52 is shown. Such intermediate coupling 52 may comprise a patch cable 54 or an EMR conduction extending segment 56 used to extend the distance between the EMR power source 26 and the optical element connector 94 of the insertable optical element 14, without appreciable loss of light intensity. Each of the patch cable 54 or EMR conduction extending segment 56 may have a forward connector 58 to securely engage coupling element 28, and a rearward connector 60 to securely engage the optical element connector 94. Hence, by using a patch cable 54 or an EMR conduction extending segment 56, the EMR power source 26 may be operated some desired distance from the patient to reduce noise or heat concerns and/or to position the EMR power source 26 closer to a power source (not shown) such as an electrical outlet or battery pack.

FIGS. 6A-C is a series of illustrative cross sectional views of alternative optical elements 14 as disposed within an exemplary single-lumen catheter 10. Of course, multi-lumen catheters 10 are also contemplated by this disclosure and the context of FIGS. 6A-C can easily be understood by those skilled in the art to apply equally to multi-lumen catheters 10 wherein one or more optical elements 14 may reside within one or more of the multiple lumens 30. The depiction of single lumen catheter 10 cross sections is provided in the interest of brevity. However, examples of multi-lumen catheters are described and depicted in the parent application (U.S. application Ser. No. 13/801,750, filed on Mar. 13, 2013) which has been incorporated into this application by a specific reference above.

FIG. 6A is a cross sectional view along line B-B of FIG. 5 showing an exemplary embodiment of a cladding-encased fiber optic 70 as centered within a lumen 30 of the catheter line tubing 16. However, FIG. 6A may also depict a cross section of a single lumen catheter 10. The single lumen line tubing 16/catheter 10, depicted in cross section, has an inner diameter 74 and a catheter wall 84. The cladding-encased fiber optic 70 is an optical element 14 and has an outer diameter 76, a core-cladding boundary 80 and a cladding outer boundary 82. When the cladding-encased fiber optic 70 is centered, as depicted in FIG. 6A, an annular void 78 is created between the cladding outer boundary 82 and the catheter wall 84 when the inner diameter 74 of the catheter wall 84 is larger than the outer diameter 76 of the cladding-encased fiber optic 70. Fluids may travel through this void 78, whether by injection or retrieval, when the cladding-encased fiber optic 70 resides within the lumen 30 of a single lumen catheter 10 (or a EMR designated lumen 30 within a multi-lumen catheter 10.

FIG. 6B is a cross sectional view along line B-B of FIG. 5 showing an exemplary embodiment of the cladding-encased fiber optic 70 non-centered within a lumen 30 of the catheter line tubing 16. Similarly, FIG. 6B may also depict a cross section of a single lumen catheter 10. However, the void 78 formed within the lumen 30 is not annular, and without structure to hold the cladding-encased fiber optic 70 in a centered disposition, the non-centered disposition may occur when the optical element 14 is removably inserted into the lumen 30 of the catheter 10. Consequently, the therapeutic EMR emitted radially from the optical element 14 must pass through the void 78 before reaching and passing through the catheter wall 84. Especially when there is fluid present within the void 78, the intensity of the therapeutic EMR may need to be increased so that the therapeutic EMR emerging from the catheter wall 84 is sufficient to inactivate infectious agents and/or to enhance healthy cell growth in the tissue surrounding the indwelling catheter 10.

FIG. 6C is a cross sectional view along line B-B of FIG. 5 showing another exemplary embodiment of a bare fiber optic 72 as centered within a lumen 30 of the catheter line tubing 16. With this embodiment, the void 78 is created between the catheter wall 84 and the exterior surface 62 of the bare fiber optic 72.

FIGS. 8A-D is a series of elevation views of several exemplary embodiments of an optical assembly 50 showing various locations with gradient degrees of alteration on the exterior surface 62 of the insertable optical element 14. Each view of the series of views shows an optical assembly 50 with an insertable optical element 14 connected to the optical element connector 94. The optical element connector 94 (see also FIGS. 7 and 9) has a connecting element 88, an EMR hub connection 90, a collimating lens 92, and an alignment shaft 98.

The first view (uppermost, FIG. 8A) of the series of views shows an unaltered optical span 100 of the insertable optical element 14 that is without any radial dispersion (i.e., the insertable optical element 14 has not been treated or altered to provide radial emission of light from the body of the insertable optical element 14). With this embodiment, therapeutic, non-ultra-violet EMR may be provided to a distal end 64 of the optical element 14 with no radial emission from the optical span 100 other than at the distal end 64.

The second view (next view down, FIG. 8B) of the series of views shows an exemplary radial transmission equivalency over a radial emission portion 103 (i.e., radial emission portion 103, as depicted, has a gradient modification such that the emitted EMR has substantially uniform intensity and power over the length of the radial emission portion 103) that provides radially dispersed light from a segment-modified optical span 102. The location of the single radial emission portion 103, in this instance, corresponds to where the catheter 10 enters the insertion site A when the insertable optical element 14 is inserted fully into the catheter 10. With this embodiment, radially emitted visual light may sterilize and/or enhance healthy cell growth at the insertion site A and the transdermal area 48 or any other predetermined site within the patient's body 12.

Each of the views in FIGS. 8B-D depicts a gradient modification to facilitate emitting EMR in a pattern wherein there is substantially uniform intensity and power over the length of the radial emission portion(s). It should be understood, however, that although each of the views depict EMR of uniform intensity and power, any desired pattern of EMR emission may be achieved by varying the degree of modification within the radial emission portion because less ablation will permit less radial emission of EMR and more ablation will permit more radial emission of EMR. For example, a radial emission portion with less oblation proximate each end and more ablation in the middle will emit EMR of lesser intensity and power on each end with more intensity and power emitting in the middle. Hence, any desired pattern of EMR emission may be created by adjusting the pattern of ablation within the radial emission portion.

The third view of the series of views (FIG. 8C) shows an example of a single radial emission portion 105 that provides radially dispersed EMR from optical element 14 extending along most of a fully-modified optical span 104. The location of the single radial emission portion 105 corresponds generally to the entire length of the insertable catheter component 22 of the catheter 10. With this embodiment, therapeutic EMR may be provided for substantially the entire length that the catheter 10 that would be inserted within the patient's body 12.

The fourth view of the series of views (FIG. 8D) shows an example of radial transmission uniformity at multiple locations. A single radial emission portion 103 and an additional distal end region radial emission portion 107 are spaced along a multi-modified optical span 106. The locations of the radial emission portion 103 and the distal end region radial emission portion 107 correspond to areas of the body, including for example the insertion site A, where the delivery of non-ultraviolet, therapeutic EMR may be desired for sterilization and/or healing. It should be understood that there may be more than one radial emission portion 103 disposed along the length of the multi-modified optical span 106 and/or each radial emission portion 103 may be distinct from each other radial emission portion 103 and each may have differing lengths.

Also, it should be understood that in each of these views the radial emission portions depicted may be of modifications other than modification of the exterior surface 62 of the insertable optical element 14, such as for example, modifications including microscopic structures embedded within the insertable optical element 14 that allow radial transmission of light from the insertable optical element 14. Further, such radial emission portions 103, 105, 107 may have gradient patterns that allow for an overall substantially-uniform distribution of light over the length of each radial emission portion 103, 105, 107.

FIG. 9 is a schematic view of an optical assembly 50 with an insertable optical element 14 coupled to an optical element connector 94. The insertable optical element 14 has a fully-modified optical span 104. Multiple locations along the insertable optical element 14 are shown in enlarged cross-sectional views. These locations are axially spaced along the insertable optical element 14 to assist in describing the nature of an exemplary insertable optical element 14 at each location. As depicted, there are four section locations, a first section 108, a second section 110, a third section 112, and a fourth section 114. For brevity, the modifications on and in the insertable optical element 14 at each of the four sections are combined in the depictions of FIG. 9. Of course, the radial emission portions of the insertable optical element 14 may be singular or multiple, may be any length or gradient, and may be coincident, overlapping or not.

The first section 108 represents an internally reflected region of the insertable optical element 14. As shown at the first section 108, there is no ablation (or other modification) and no microscopic structure within the core 66 of the insertable optical element 14. No therapeutic non-ultraviolet EMR will emit radially from the insertable optical element 14 at the first section 108.

The second section 110 represents a minimally emissive region of the insertable optical element 14. As shown at the second section 110, there is minimal ablation (or other modification) to the exterior surface 62 of the insertable optical element 14 and a minimal dispersal of microscopic structures 117 within the core 66 of the insertable optical element 14. From the second section 110, minimal therapeutic, non-ultraviolet EMR will emit radially from the insertable optical element 14. However, the amount of EMR emitted should have sufficient intensity and power to inactivate infectious agents and/or promote healing proximate the second section 110.

The third section 112 represents a moderately emissive region of the insertable optical element 14. As shown at the third section 112, there is moderate ablation (or other modification) to the exterior surface 62 of the insertable optical element 14 and moderate dispersal of microscopic structures 117 within the core 66 of the insertable optical element 14. From the third section 112, a moderate amount of therapeutic, non-ultraviolet EMR will emit radially from the insertable optical element 14 proximate the third section 112. However, prior to reaching the third section 112, the amount of light traveling axially along the insertable optical element 14 diminishes due to the radial emission of some of the light such as at second section 110. Consequently, the degree of the gradient of modification is selected so that the amount of EMR emitted radially at third section 112 should be substantially uniform with the radial emission at the second section 110. Hence, the intensity and power of the EMR emitted may be substantially uniform with the intensity and power emitted at second section 110 and is of sufficient intensity and power to inactivate infectious agents and/or promote healing.

The fourth section 114 represents a maximally emissive region of the insertable optical element 14. As shown at the fourth section 114, there is maximal ablation (or other modification) to the exterior surface 62 of the insertable optical element 14 and maximal dispersal of microscopic structures 117 within the core 66 of the insertable optical element 14. From the fourth section 114, a maximum amount of therapeutic, non-ultraviolet EMR will emit radially from the insertable optical element 14 proximate the fourth section 114. Again, prior to reaching the fourth section 114, the amount of light continuing to travel axially along the insertable optical element 14 diminishes due to the radial emission of some of the light such as at second section 110 and at third section 112. Consequently, the degree of the gradient of modification is selected so that the amount of EMR emitted radially at fourth section 114 should be substantially uniform with the emissions at second section 110 and third section 112. The intensity and power of the EMR emitted may be substantially uniform with the intensity and power emitted at second section 110 and third section 112 and is of sufficient intensity and power to inactivate infectious agents and/or promote healing.

The radial emission portions may be modified by chemical, physical or other cladding modification (e.g., ablation) to alter the critical angle enough to allow light to emit radially. Additionally or alternatively, the radial emission portions may be modified by dispersing microscopic structures 117 of varying gradient concentration inside the core 66 of the insertable element 14. The gradient concentration of microscopic structures 117 within the core 6 shown in FIG. 9 range from a microscopic structures free area 109, to a minimal concentration 111 of microscopic structures 117, to a moderate concentration 113 of microscopic structures 117, to a maximal concentration 115 of microscopic structures 117.

The concentration of microscopic structures 117 within the core 66 affects the refractive index of the core 66 and the core-cladding boundary 80. The microscopic structures 117 (which may be, for example, reflective flakes or voids, such as bubbles) create changes in the incident angle of the light as it passes through the insertable optical element 14. At certain incident angles, light leaves the optical element cladding 68 and emits radially from the cladding outer boundary 82.

FIG. 10 is a schematic view of the cross-sectional views of FIG. 9 depicting light rays as arrows. The same cross-sectional views of the insertable optical element 14 are shown: namely, the first section 108 (internally reflected), the second section 110 (minimally radially emissive), the third section 112 (moderately radially emissive), and the fourth section 114 (maximally radially emissive). These views also show light rays traveling axially along the core 66, that collide with microscopic structures 117 at an incident angle causing the light ray to pass through the optical element cladding 68. An increasing pixilated gradient is depicted on the cladding boundary 82 from the first section 108 (no pixilation), to the second section 110 (minimal pixilation), to the third section 112 (moderate pixilation), to the fourth section 114 (maximal pixilation) represents the chemical, physical or other cladding modification (e.g., ablation) at the cladding boundary 82. Such modification of the insertable optical element 14 alters critical angles enough to allow light to emit radially. As schematically depicted, the amount of rays leaving the optical element cladding 68 are substantially equivalent at each site although the amount of rays the core 66 diminishes as the light travels from proximal to distal. The microscopic structures 117 of varying gradient concentration are also shown inside the core 66, from the microscopic structure free area 109, to a minimal concentration 111, to a moderate concentration 113, to a maximal concentration 115. Each of the microscopic structures 117 has a refractive index that differs from that of the core 66 and the optical element cladding 68. The microscopic structures 117 (which may be, for example, reflective flecks or voids, such as bubbles) create changes in the incident angle of the light as it passes through the insertable optical element 14. At certain incident angles, light leaves the optical element cladding 68 and emits radially.

FIG. 11 shows cross-sectional views of various exemplary dispersals of microscopic structures 117 (such as flecks or bubbles) within a fiber optic's core 66, cladding 68, and the core/cladding boundary 80. With each of the exemplary embodiments depicted microscopic structures 117 are dispersed within the insertable optical element 14 (in this case an optical fiber) to achieve radial transmission of light. These microscopic structures 117 may be positioned within the core 66 and/or at the core-cladding boundary 80 and/or within the cladding 68 of the optical fiber 14. The microscopic structures 117 having a refractive index lower than the region free of microscopic structures 117. The microscopic structures 117 may be a material added to the optical fiber core 66 or the core-cladding boundary 80, such as a metal, rubber, glass beads, or plastic. The microscopic structures 117 may also be the lack of material creating an aberration within the optical fiber core 66 and/or the core-cladding boundary 80 and/or within the cladding 68. For example, the presence of microscopic structures 117 (such as bubbles) in the optical fiber core 66 creates an aberration or imperfection that would alter the materials refractive index, resulting in EMR being emitted radially from the optical fiber (insertable optical element 14).

In FIG. 11, three exemplary dispersals, a first dispersal 121, a second dispersal 123, and a third dispersal 125, are depicted. The first dispersal 121 has microscopic structures 117 (such as flecks or bubbles) dispersed within and outer region 127 of the core 66 only. The second dispersal 123 has microscopic structures 117 dispersed within an inner region 129 of the cladding 68 as well as within the outer region 127 of the core 66. The third dispersal 125 has microscopic structures 117 dispersed proximate to the core/cladding boundary 80 and are depicted as identifying a boundary region 131 that is thinner than the outer region 127 of the core 66 and the inner region 129 of the cladding 68. With each of these exemplary dispersals, at least some of the light traveling the length of the insertable optical element 14 (fiber optic) will not encounter any microscopic structures 117 while the remainder of the light may encounter at least one microscopic structure 117 and be deflected to emit radially from the insertable optical element 14.

FIG. 12 is a schematic view of an exemplary optical element modification method for creating gradient modification on the exterior surface 62 of the insertable optical element 14. Such modification of the core 66 or optical element cladding 68 alters the incident angle of light rays so that they differ from the critical angle needed to remain internally reflected. Depicted in FIG. 12 is a control device 122 with a wand 124 delivering an acid spray 126 for etching the insertable optical element 14.

There are several methods for achieving this gradient modification. Chemically, the insertable optical element 14 may be etched using a strong acid such as hydrofluoric acid or sulfuric acid and hydrogen-peroxide. Also, quartz powder, calcium fluoride, or an etching cream, usually carrying a fluorinated compound, may be used. Physically, heating the insertable optical element 14 or physical modification such as ablation by sanding, media blasting, grinding, or laser ablation modifications are also methods for creating gradient modification. Additionally, plasma ablation by laser modification causes the ionization of molecules and alteration of the exterior surface 62 of the insertable optical element 14. Other known methods for creating gradient ablation are contemplated by this disclosure. Regardless of the modification or manufacturing process, whether presently known or not, the insertable optical element 14 may be modified to have substantially equivalent radially emitted light along desired lengths. This uniformity in radially emitted light allows for a more accurate treatment dose for inactivating infectious agents and/or promoting healing.

In FIGS. 8A-D, 9, and 12 of the present disclosure, a transparent view of the optical element connector 94 is depicted, comprising a connecting element 88, an EMR hub connection 90, a collimating lens 92, and an alignment shaft 98. The insertable optical element 14 may be inserted into an aligning bore of the optical element connector 94 to collimate the light into a small diameter core 66 or one or more optical fibers.

The exemplary disclosure depicts an optical diversion element as a single collimating lens 92, but other types of optical diversion elements such as multiple lenses or different types of lenses may be used to collimate the light. Depending on the optical element 14 diameter, numerical aperture, and refractive index, specific lenses will be needed as an optical diversion element to reduce light loss.

Turning now to FIG. 13, a urinary catheter assembly is depicted. The urinary catheter assembly comprises and electromagnetic radiation component 20 and an insertable catheter component 22. The insertable catheter component comprises a proximal catheter hub assembly 32, an elongate catheter body 36 and a distal end 34 region. The proximal catheter hub assembly 32 serves as an input port 43 (the arrow showing the direction of fluid flow and/or therapeutic EMR propagation 162). The elongate catheter body 36 also comprises an output port 45 for draining urine from the patient (the arrow showing the direction of urine flow 164), an inflatable balloon cuff 37 (shown inflated), and an aperture 35, the balloon cuff 37 and aperture 35 are disposed within the distal end 34 region. The insertable catheter component 22 may be made in varying lengths 38 as female urinary catheters are typically shorter than male urinary catheters which are made to different lengths.

The electromagnetic radiation component 20 comprises an EMR power source 26, a coupling element 28, and an optical element 14. As depicted, the coupling element 28 is spaced from the catheter hub assembly 32 to reveal the optical element 14 that is partially inserted into the lumen of the elongate catheter body 36. When the coupling element 28 is connected to the catheter hub assembly 32, the optical element will be fully inserted and the distal end of the optical element 14 will extend to the termination 42 so not to interfere with the inflatable balloon cuff 37 or the aperture 35. In this fully inserted disposition, the optical element 14 may emit radially therapeutic EMR at the incision site A and into the transdermal area 48.

FIG. 14 depicts another exemplary urinary catheter 10 as positioned within a male patient. As shown, the urinary catheter 10 has been inserted into the patient's bladder 41 through the urethra 39 and the balloon cuff 37 has been inflated to seal the bladder 41 from leaking around the urinary catheter 10. This exemplary urinary catheter 10 comprises an elongate catheter body 36, an adapter 150, a securing sleeve 152, and a drain tube 154. The adapter 150 has an input port 43 and an output port 45. An EMR component 20 may be utilized in conjunction with the exemplary urinary catheter 10 to provide therapeutic EMR along the urethra 39 and into the bladder 41 to inactivate infectious agents and/or to promote healthy cell growth. The EMR component 20 comprises a control device 154 that houses an EMR power source 26, operational control features 156 and a display 158, an optical element 14, and an optical jack 160.

When positioned as shown in in FIG. 14, the optical element 14 has been threaded into the adapter 150 and secured by the securing sleeve 152 and urine freely drains through the elongate body 36 into the drain tube 154 to be deposited in a urine drain bag (not shown). Frequently, urinary catheters 10 are indwelling for long periods of time and consequently are a concern for the build-up and proliferation of infectious agents in or around the urinary catheter 10. To provide therapeutic EMR to prevent, reduce, or eliminate the proliferation of infectious agents and/or to enhance healthy cell growth, the optical jack 160 is plugged into the control device 154 connecting the optic al element 14 to the EMR power source 26 and the operational control features 156 are activated to set the frequency or frequencies, intensity, power, duty cycle, and other operational parameters, and turn on the EMR delivery into the optical element 14. The setting of the operational features and the monitoring of the parameters may be viewed on the display 158.

For exemplary methods or processes of the invention, the sequence and/or arrangement of steps described herein are illustrative and not restrictive. Accordingly, it should be understood that, although steps of various processes or methods may be shown and described as being in a sequence or temporal arrangement, the steps of any such processes or methods are not limited to being carried out in any particular sequence or arrangement, absent an indication otherwise. Indeed, the steps in such processes or methods generally may be carried out in various different sequences and arrangements while still falling within the scope of the present invention.

Additionally, any references to advantages, benefits, unexpected results, or operability of the present invention are not intended as an affirmation that the invention has been previously reduced to practice or that any testing has been performed. Likewise, unless stated otherwise, use of verbs in the past tense (present perfect or preterit) is not intended to indicate or imply that the invention has been previously reduced to practice or that any testing has been performed.

Exemplary embodiments of the present invention are described above. No element, act, or instruction used in this description should be construed as important, necessary, critical, or essential to the invention unless explicitly described as such. Although several exemplary embodiments have been described in detail herein, those skilled in the art will readily appreciate that many modifications are possible in these exemplary embodiments without materially departing from the novel teachings and advantages of this invention. Accordingly, all such modifications are intended to be included within the scope of this invention as defined in the appended claims.

In the claims, any means-plus-function clauses are intended to cover the structures described herein as performing the recited function and not only structural equivalents, but also equivalent structures. Thus, although a nail and a screw may not be structural equivalents in that a nail employs a cylindrical surface to secure wooden parts together, whereas a screw employs a helical surface, in the environment of fastening wooden parts, a nail and a screw may be equivalent structures. Unless the exact language “means for” (performing a particular function or step) is recited in the claims, a construction under Section 112, 6th paragraph is not intended. Additionally, it is not intended that the scope of patent protection afforded the present invention be defined by reading into any claim a limitation found herein that does not explicitly appear in the claim itself.

While specific embodiments and applications of the present invention have been illustrated and described, it is to be understood that the invention is not limited to the precise configuration and components disclosed herein. Various modifications, changes, and variations which will be apparent to those skilled in the art may be made in the arrangement, operation, and details of the methods and systems of the present invention disclosed herein without departing from the spirit and scope of the invention. 

What is claimed is:
 1. A medical device assembly for insertion into a cavity of a patient's body and for delivery of a fluid to and/or retrieval of fluid from the patient's body, comprising: an electromagnetic radiation (EMR) source for providing non-ultraviolet, therapeutic EMR having an intensity comprising a radiant exposure of at least 0.1 J/cm² and up to 1.0 kJ/cm² and power of at least 0.005 mW and up to 1 Watt, such intensity being sufficient to produce a therapeutic effect of at least one of inactivating one or more infectious agents and enhancing healthy cell growth; a catheter having an elongate catheter body with at least one internal lumen, a coupling end and an distal end, the distal end being insertable into the cavity of the patient's body, wherein the catheter body directs both the fluid and the therapeutic EMR axially relative to the catheter body, axial flow of the fluid within the catheter body facilitates at least one of delivery of fluid into the patient's body and retrieval of fluid from the patient's body; an optical element conducive to the axial propagation of the therapeutic EMR relative to the catheter body, the optical element having a position with respect to the catheter body of being at least one of in, on, or within a wall of the catheter body and within at least one internal lumen of the catheter body; and at least one coupling to connect the EMR source to the catheter body.
 2. The medical device assembly as in claim 1 wherein the catheter body is configured for access to at least one cavity of the patient's body, such cavity being at least one of a venous, an arterial, a gastrointestinal, an abdominal, a urological, a respiratory, a cranial, and a spinal cavity.
 3. The medical device assembly as in claim 1 wherein the at least one internal lumen comprises a propagation lumen for the axial propagation of the therapeutic EMR relative to the catheter body.
 4. The medical device assembly as in claim 1 wherein the optical element is selected from a group of optical elements including a reflective surface, a lens, a fiber optic filament, and any combination thereof.
 5. The medical device assembly as in claim 1 wherein at least a portion of the optical element comprises a fiber optic filament for disposition within the at least one internal lumen, the fiber optic filament comprises a fiber body having at least a portion configured as at least one of a bare fiber body and a cladding-encased fiber body, the fiber body having an exterior surface, a coupling end, a distal end, and a core, the fiber optic filament being conducive to the axial propagation of therapeutic EMR within the core.
 6. The medical device assembly as in claim 5 wherein the fiber optic filament further comprises at least one radial emission portion on the exterior surface disposed between the coupling end of the fiber body and the distal end of the fiber body, the radial emission portion allowing the emission of therapeutic EMR radially from the fiber body into the lumen of the catheter.
 7. The medical device assembly as in claim 6 wherein at least one radial emission portion-directs therapeutic EMR of a desired intensity radially through and along the length of each radial emission portion into the internal lumen of the catheter.
 8. The medical device assembly as in claim 7 wherein the radial emission portion comprises an ablated surface, the ablated surface having a gradient ablation, the gradient ablation having a gradient pattern such that the emission of EMR radially from the radial emission portion has a uniform intensity.
 9. The medical device assembly as in claim 1 wherein the therapeutic EMR has a wavelength that ranges from about 380 nm to about 904 nm.
 10. The medical device assembly as in claim 5 wherein the internal lumen has an inner diameter and the fiber body has an outer diameter, the inner diameter of the internal lumen being greater that the outer diameter of the fiber body, thereby defining a void within the internal lumen external to the exterior surface of the fiber body.
 11. The medical device assembly as in claim 10 wherein the void facilitates the passage of fluid through the void by at least one of delivery of fluid to and retrieval of fluid from the patient's body simultaneously with at least a portion of the fiber body being disposed within the internal lumen.
 12. The medical device assembly as in claim 10 wherein at least a portion of the optical element is removably insertable into the internal lumen.
 13. The medical device assembly as in claim 1 wherein the catheter is a urinary catheter.
 14. A medical device assembly for insertion into a cavity of a patient's body and for delivery of fluid to and/or retrieval of fluid from the patient's body, comprising: an electromagnetic radiation (EMR) source selected from a group including a solid state laser, a semiconductor laser, a diode laser, and a light emitting diode, the EMR source for providing non-ultraviolet, therapeutic EMR having a wavelength in a range of above 380 nm to 904 nm and having an intensity comprising a radiant exposure of at least 0.1 J/cm² and up to 1.0 kJ/cm² and power of at least 0.005 mW and up to 1.0 Watt, such intensity being sufficient to produce a therapeutic effect of at least one of inactivating one or more infectious agents and enhancing healthy cell growth; a catheter having an elongate catheter body with at least one internal lumen, a coupling end and an distal end, the distal end being insertable into the cavity of the patient's body, wherein the catheter body directs both the fluid and the therapeutic EMR axially relative to the catheter body for at least one of delivery of fluid into the patient's body and retrieval of fluid from the patient's body; an optical element conducive to the axial propagation of the therapeutic EMR relative to the catheter body, the optical element having a position with respect to the catheter body of being at least one of in, on, or within a wall of the catheter body and within at least one internal lumen of the catheter body; and at least one coupling to connect the radiation source to the catheter body.
 15. The medical device assembly as in claim 14 wherein the wavelength of the therapeutic EMR is selected from a group of wavelengths including wavelengths centered about 400 nm, 405 nm, 415 nm, 430 nm, 440 nm, 445 nm, 455 nm, 470 nm, 475 nm, 632 nm, 632.8 nm, 640 nm, 650 nm, 660 nm, 670 nm, 680 nm, 780 nm, 808 nm, 830 nm, and 904 nm.
 16. The medical device assembly as in claim 15 wherein the therapeutic EMR comprises one or more of the selected wavelengths being emitted in at least one of alternating and parallel treatment patterns.
 17. The medical device assembly as in claim 14 wherein the EMR source has an adjustable duty cycle length.
 18. A method for delivering therapeutic electromagnetic radiation (EMR) into an internal lumen of a catheter disposed within a cavity of a patient's body to produce a therapeutic effect within the catheter and/or the patient's body, the method comprising the steps of: positioning at least a portion of an optical element within the internal lumen of the catheter having an elongate catheter body, the optical element being conducive to the axial propagation of a therapeutic EMR relative to the catheter body; connecting an EMR source to the optical element, the EMR source for providing non-ultraviolet, therapeutic EMR having an intensity comprising a radiant exposure of at least 0.1 J/cm² and up to 1.0 kJ/cm² and power of at least 0.005 mW and up to 1.0 Watt, such intensity being sufficient to produce a therapeutic effect of at least one of inactivating one or more infectious agents and enhancing healthy cell growth; and activating the EMR source to produce the therapeutic effect within the cavity of the patient's body.
 19. The method as in claim 18 wherein the optical element comprises at least one radial emission portion on an exterior surface of the optical element, the method further comprising the step of emitting radially therapeutic EMR from the radial emission portion of the optical element into the lumen of the catheter.
 20. The method as in claim 19 wherein the radial emission portion comprises an ablated surface, the ablated surface having a gradient ablation, the method further comprising the step of creating the gradient ablation by ablating the exterior surface of the optical element in a gradient pattern such that the emission of EMR radially from the radial emission portion has a desired intensity. 